Well, Kryon says this is where to look to solve the problem of our own pollution, and it IS happening....
And I suppose this is old news since there's been quite a bit about
this information in the regular news...but wouldn't you think
someone would heavily invest in this stuff and transform our most deadly
wastes quickly??? Let's speed it up!
See you soon,
Kathy
ScienceDaily -- 9/9/1998
Source: University Of Idaho
Researchers Find New Microbes At Work On Mine Tailings In Lake Coeur D'alene
MOSCOW, Idaho - Certain naturally-occurring bacteria living in the floor
of Lake Coeur d'Alene may be helping to prevent the
release of contaminants such as lead and zinc into lake waters, according
to a University of Idaho scientist. These benefits,
however, could be offset by other bacteria whose activities favor the
release of other contaminants, such as arsenic.
UI biology Professor Frank Rosenzweig and graduate students Jim Harrington
and Dave Cummings, both of Moscow, recently
published research findings that indicate microorganisms living within
or near the floor of the lake are transforming some of the
most potentially dangerous heavy metals - such as lead and zinc - from
a water-soluble state to a much safer solid state. The
viability - and consequently the activity - of many such organisms
depends on keeping the sediments free of oxygen.
"This is a fertile area for research because these microbes can actually
change elements from one state to another," Rosenzweig
said. "My gut feeling right now is the best thing we can do for the
lake is leave it alone. To go in and dredge the lake as some have
suggested would be, to say the very least, unwise. But leaving it alone
may also entail minimizing human impacts that often result
from over development."
Rosenzweig's research is funded through the National Science Foundation's
EPSCoR project and is being published in refereed
scientific journals such as, "Environmental Science and Technology"
and "Journal of Environmental Quality." He said that until now
the vast majority of research done on northern Idaho's Lake Coeur d'Alene
has been chemical in nature. "There really has been
no microbiological work done on sediments in the lake," he said.
Rosenzweig, Cummings and Harrington have taken samples from the lake
floor at several sites near the mouth of the Coeur
d'Alene River near Harrison. That's where previous research has shown
the highest level of heavy metals and mine tailings to be.
They also took samples from the lake floor where the St. Joe River
flows into the lake. It has virtually no heavy metal
contamination, and therefore, serves as a control site. The sampling
method involves retrieving sediments as intact, 0.5-meter
cores encased in PVC tubes.
In previous studies similar samples were shipped to laboratories outside
the region. Rosenzweig's group preserved both the
temperature and pressure conditions in which the samples - both those
at the surface of the floor and up to 60 centimeters into the
floor - were found. They rushed the samples back to the Moscow campus
to conduct a thorough chemical analysis to pinpoint the
location and state of the heavy metals.
The samples were then exposed to harsher and harsher chemical processes
to see under what conditions the heavy metals would
be stripped from the sediment and returned to a water-soluble state.
"We found that irrespective of depth, the majority of metal
contaminants were associated with a sulfidic phase. This phase is insoluble
under the neutral pH, oxygen-free conditions that
prevail in these lake sediments," Rosenzweig said. "Furthermore, lead
and zinc are almost always found together in the deepest
layers of the sediment."
Significantly, the scientists also found that arsenic and iron - heavy
metals presumably deposited at the same time as the lead and
zinc - were most prevalent in uppermost sediment layers, often within
4 to 5 inches of the overlying waters. Their location seems
to coincide with the point where oxygen disappears.
The observation that metals have different distribution patterns led
Rosenzweig and his group to hypothesize that metals are being
actively transformed within Lake Coeur d'Alene. These transformations
involve the change of metals from one compound to
another. Since different compounds have different solubilities in water,
they can result in the movement of metals between solid
and liquid phases.
"These 'transformations' are both chemical and biological in nature,"
Rosenzweig said. "But the extent to which microbes control
these processes has only recently become apparent. Bacteria not only
deplete the sediments of oxygen, they can also respire iron,
arsenic and sulfate in much the same way we use oxygen."
Microbes that respire sulfate produce hydrogen sulfide (marsh gas).
Sulfide can chemically combine with metals to render them
insoluble, and therefore, less likely to enter the food chain. "A metal
sulfide that is familiar to everybody is fool's gold or pyrite,"
said Rosenzweig. "The sparkle at the bottom of our streams testifies
to the stability of these compounds in water."
On the other hand, microbes that respire iron or arsenic could contribute to iron and arsenic instability.
"The activities of microbes underlie the peculiar distribution patterns
of these elements in contaminated sediments such as Lake
Coeur d'Alene," Rosenzweig said. "Whether or not these particular elements
could ever be released into overlying waters is an
open question. Clearly, we need to better understand the system with
respect to the consequences of human disturbance. And
disturbance in my book includes not just mechanical things, such as
dredging, but increased nutrient levels that could occur if the
lake were overdeveloped."
Each spoonful of Lake Coeur d'Alene sediment contains more than a million
microbes. Preliminary work suggests that these
sediments support tremendous biodiversity. The UI scientist and his
graduate students have isolated "entirely new species and
genera of bacteria."
"When I started graduate school I never thought I would ever have the
fun of describing and naming new organisms," Rosenzweig
said. "Moreover, these discoveries may prove to have commercial benefits.
"Depending on the conditions you design - or face - these bacteria could
be used for biological mining or for the bioremediation of
existing mining sites. After all, in order to survive, these creatures
either had to have evolved or come equipped with the ability to
tolerate extremely high levels of heavy metals."
Rosenzweig and his group are headed back to the waters of Lake Coeur
d'Alene early this month to take more core samples of
the lake floor. The group now includes post-doctoral fellow Bruce Wielenga,
and doctoral students Tony March, Srivi
Ramamoorthy, Allison Niggenmeyer and Matthew LaForce. Among their projects
will be microcosm experiments to test how the
bacterial community responds to additional sedimentation as well as
increases in nutrients like nitrogen or phosphate. The team will
then record how these changes affect the location and abundance of
heavy metals.
"To me, the science seems to be saying, 'Leave the lake alone' and 'Restrict
development,'" Rosenzweig said. "If we do that, the
amount of heavy metals in the lake water may remain acceptable. But
a definite answer as to how much development the lake
can tolerate will depend strictly on more research."